KR20080039282A - Electronic apparatus, charging method therefor, and battery - Google Patents

Abstract

An electronic apparatus, a charging method therefor, and a battery are provided to charge the battery in a desired condition for each battery without awareness. An electronic apparatus(100) includes a battery(190), a body, a charging member, an acquisition member, and a control member. The battery has first information for controlling charge. The body operates by using the battery as a power source. The charging member charges the battery. The acquisition member acquires the first information from the battery. The control member executes the charge according to different batteries by controlling the charging member based on the acquired first information. The first information is the maximum charging amount of the battery. The control member stops the charge of the battery when the battery has the maximum charging amount.

Description

ELECTRICAL APPARATUS, CHARGING METHOD THEREFOR, AND BATTERY}

TECHNICAL FIELD This invention relates to the electronic device which can be operated by the battery (secondary battery), such as a notebook type personal computer, the charging method of an electronic device, and its battery, for example.

In the case of a lithium ion battery used abundantly in mobile electronic devices such as a notebook personal computer, there is a characteristic that the voltage inside the battery cell changes depending on the amount of charge (remaining amount) of the battery. In other words, when charging proceeds, the voltage on the battery cell side increases. For example, for a battery cell with a nominal voltage of 4.2 V, the voltage on the battery cell side is 4.2 V when the charge is 100%, but 4.0 V when the charge is 80%, and 3.7 V when the charge is 50%. The voltage on the battery cell side drops.

On the other hand, a lithium ion battery has the characteristic that the higher the battery cell voltage is, the easier it is to elute the positive electrode active material constituting the battery, and the performance deterioration of the battery becomes remarkable. In other words, if long term storage is performed in a state where the cell voltage is high, battery performance is degraded and capacity deterioration proceeds. This means that long-term storage in a state where the cell voltage is high shortens the battery life. Therefore, it is possible to suppress the deterioration of the capacity of the battery by suppressing the charge amount of the battery to 80% or 50%, for example, with respect to the maximum charge capacity (100%) of the battery.

More specifically, for example, a user of a notebook type personal computer has two batteries having different capacities. Here, a battery with a large capacity is called an L battery, and a battery with a small capacity is called an S battery. If the maximum charging capacity of the battery is fixed (determined) on the main body side, "L battery has a large capacity, so it can be charged up to 80% to suppress deterioration, and S battery can be set to 100% for a duration of time. I want to give priority to this. ”

Moreover, in such a lithium ion battery, as a charge / discharge rate (C) becomes high, there exists a tendency for charge / discharge cycle characteristics to deteriorate. On the other hand, when the charging rate is high, the charging time is short. On the contrary, when the charging rate is low, the charging time is long. Here, the charge / discharge rate (C) means the ratio of the charge / discharge current to the nominal current capacity of the battery. 1C corresponds to the amount of current equivalent to the nominal capacity. For example, in the case of the nominal capacity 2600 mH, 0.5C is 1300 mW. In addition, a charge / discharge cycle characteristic means the phenomenon in which battery capacity falls by repeating charge / discharge, or its ratio. Therefore, in consideration of the charging time and the charge / discharge cycle characteristics, it is generally set at an appropriate charging rate.

The personal computer main body may support plural kinds of batteries having different pack capacities because of different numbers of parallel cells or different cell capacities. In this case, too, the charging current of the charging circuit is generally fixed and operated.

However, when the optimal charging current is flowed to the battery having a large pack capacity to the battery having a small pack capacity, the charging rate is increased, and the battery life is shortened for the reasons described above. On the contrary, when the optimum charging current is supplied to a battery having a small pack capacity to a battery having a large pack capacity, a problem may occur such that the charging time becomes longer than necessary or the charge completion cannot be detected correctly.

Therefore, for example, Patent Document 1 describes a technique of varying the charging amount by a switch on the main body side. It is conceivable to apply the same technique to the charging current.

[Patent Document 1] Japanese Patent Laid-Open No. 2002-78222 (paragraph [0006], FIG. 3)

However, in the technique of switching the charging amount and the charging current by the switch on the main body side, it is necessary to change the setting every time the battery is changed and plugged in, which impairs the convenience. In addition, the user may forget to switch or may not even know to switch.

In view of the above circumstances, an object of the present invention is to provide an electronic device, a charging method of an electronic device, and a battery which can charge a battery on a condition desired for each battery without being aware of the user.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, the electronic device which concerns on the main aspect of this invention is the battery which has the 1st information which can control charging, the main body which operates with the said battery as a power source, and the charge which charges the said battery. Means, means for obtaining first information from the battery, and control means for controlling charging to the battery by the charging means based on the obtained first information.

In the present invention, since the battery side has the first information capable of controlling the charge, and the charge to the battery is controlled based on the first information, the battery is charged to the battery under desired conditions for each battery without being aware of the user. Can be done. Here, the first information is most preferably rewritable from the main body side, but, as described later, includes a serial number recorded in the battery, for example.

In the present invention, the first information may be the maximum charge amount of the battery, and the control means may stop charging the battery when the control means reaches the maximum charge amount of the battery.

In the present invention, the user can be charged up to the maximum charge amount of a desired battery without being aware of it.

In the present invention, the maximum charge amount of the battery as the first information may be set to a desired value for each battery.

In the present invention, the user can set the maximum charge amount of the battery to a desired value for each battery, and after that, the user can charge up to the maximum charge amount of the desired battery for each battery without being conscious of the user.

In the present invention, after the charging means stops charging the battery, the control means may resume charging the battery by the charging means when the battery becomes a predetermined charging amount less than or equal to the maximum charging amount.

Repetition of charge and discharge in the vicinity of the threshold of the maximum charge amount Depending on the battery, there is a type that uses a different remaining amount management calculation method between the charge mode and the discharge mode. In that case, when switching from a charging mode to a discharge mode, a charge amount may fall. For example, it is assumed that the target charge amount is set to 80%. When the charge is stopped when the charge amount reaches 80%, the battery is switched from the charge mode to the discharge mode. In that case, there is a case where the remaining value becomes 79%. Therefore, when the main body side starts recharging, it immediately becomes 80%, and charging ON / OFF to stop charging is frequently repeated. Continuous repetition of charging and discharging may also cause deterioration in the battery. Therefore, in the present invention, hysteresis is provided, and after the stop of charging, for example, control is not performed until the remaining amount drops to less than 78%.

According to the present invention, there is provided a storage means for storing the unique number of the battery and the maximum charge amount of the battery in association with each other, wherein the first information is a unique number of the battery, and the control means includes the obtained first number. The maximum charge amount of the battery corresponding to the unique number of the battery as the information may be obtained from the storage means, and the charging to the battery may be stopped when the maximum charge amount of the battery is reached.

As a unique number of a battery, it is a serial number etc. recorded in the said battery, for example, In this invention, it is unnecessary to have special information on a battery side by using the unique number of a battery as 1st information.

In the present invention, even when the first information is a charging current of the battery, the control means is configured to perform charging to the battery by the charging means by the charging current of the battery as the first information. do.

In the present invention, the user can be charged with the charging current of the desired battery without being aware of it.

In the present invention, the control means has a predetermined setting function, and when the control means normally charges the battery by the charging means by a predetermined charging current, and is set by the setting function. The charging current of the battery as the first information may be configured to perform charging to the battery by the charging means.

In the present invention, the battery can be charged based on the first information by the user's selection. For example, charging of the battery in the normal mode and charging to the battery based on the first information can be left to the user's selection.

The present invention has setting means for setting the charging current of the battery to a value capable of rapid charging, and wherein the control means sets the set charging current when the charging current is set to a value capable of rapid charging by the setting means. The battery may be configured to perform charging to the battery by the charging means by a charging current capable of rapid charging.

In the present invention, it is possible to perform rapid charging in accordance with a user's request.

A charging method for an electronic device according to another aspect of the present invention is a charging method for an electronic device that operates using a rechargeable battery as a power source, and has the first information capable of controlling the charging on the battery. And obtaining the first information and controlling the charging to the battery based on the obtained first information.

In the present invention, since the battery side has the first information capable of controlling the charge, and the charge to the battery is controlled based on the first information, the battery is charged to the battery under desired conditions for each battery without being aware of the user. Can be done.

In this invention, when the said 1st information is the maximum charge amount of the said battery and it becomes the said control as the maximum charge amount of the said battery as said 1st information, you may be set as the structure which stops charging to the said battery.

In the present invention, the user can set the maximum charge amount of the battery to a desired value for each battery, and after that, the user can charge up to the maximum charge amount of the desired battery for each battery without being conscious of the user.

In the present invention, the maximum charge amount of the battery as the first information may be set to a desired value for each battery.

In the present invention, the user can set the maximum charge amount of the battery to a desired value for each battery, and after that, the user can charge up to the maximum charge amount of the desired battery for each battery without being conscious of the user.

In the present invention, the first information is the charging current of the battery, and as the control, the battery may be charged by the charging current of the battery as the first information.

In the present invention, the user can be charged with the charging current of the desired battery without being aware of it.

A battery according to still another aspect of the present invention includes a battery main body and storage means for storing first information capable of controlling charging to the battery main body.

In the present invention, the battery can be charged under a desired condition for each battery without the user being aware of it.

In this invention, the said 1st information may be set as the structure which is the maximum charge amount to the said battery main body.

In the present invention, the user can be charged with the desired charging current of the desired battery for each battery without being aware of it.

In the present invention, the first information may be configured to be a charging current to the battery main body.

In the present invention, the user can be charged with the charging current of the desired battery without being aware of it.

According to the present invention, the battery can be charged under desired conditions for each battery without the user being aware of it.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing.

1 is a block diagram showing the configuration of a notebook personal computer as an electronic apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the personal computer 100 includes a central processing unit (CPU) 110, a liquid crystal display device (LCD) 120, a memory 130, and a north bridge. 140, Hard Disk Drive (HDD) 150, South Bridge 160, Embedded Controller (EC) 170, Battery Charger 180, and this personal computer The main part is comprised from the battery 190 which can be attached or detached with respect to the main body. Here, the body of the personal computer 100 refers to a portion of the personal computer 100 excluding the battery 190.

The CPU 110 collectively controls the whole personal computer 100. The liquid crystal display device 120 displays the screen in this personal computer 100. The memory 130 stores necessary programs and is also a working memory for processing. The north bridge 140 manages the liquid crystal display device 120, the memory 130, and the like. The hard disk drive 150 stores data, programs, and the like. The south bridge 160 manages the hard disk drive 150 and the like.

The embedded controller 170 exists as a device that a normal notebook personal computer 100 has, and in the case of the personal computer 100 shown here, it has three functions largely divided. Although the embedded controller 170 is a device that should perform power management, which is originally defined by keyboard-related processing or ACPI (Advanced Configuration and Power Interface), in this case, the embedded controller 170 manages the remaining resources of the device. By utilizing, the additional function according to the present invention can be realized. In other words,

(1) Keyboard Controller (KBC): Keyboard Control

(2) ACPI / EC: power management corresponding to ACPI

(3) Programmable IO Controller: Provides interface with utility

By using this Programmable IO Controller, it communicates with utility software which is a man machine interface, and the user can obtain the information set through the utility. In addition, on the contrary, information included in the embedded controller 170 may be visually provided to the user through a utility.

 2 is a block diagram showing the relationship between the embedded controller 170, battery 190 and battery charger 180 on the hardware side, and utility software 210 on the operating software (OS) side.

 The embedded controller 170 has the following functions with respect to the battery 190.

(1) The remaining capacity of the battery 190 can be obtained from the battery 190 via the SM-BUS (System Management Bus) 200 or the like.

(2) Since the ON / OFF control signal for the battery charger 180 is provided, charging can be stopped regardless of the remaining amount of the battery 190.

(3) Presence (extraction and insertion of the battery) of the battery 190 can be detected.

The battery charger 180 charges the battery 190.

The utility software 210 is software that runs on an OS, and the main role is as follows.

(1) It functions as a man machine interface for setting a target charge amount of a battery.

(2) Visually express the current set value.

(3) When the setting is changed, the embedded controller 170 is notified of it.

FIG. 3 is a diagram illustrating an example of the utility screen 220 displayed on the screen by the utility software 210.

On the screen shown in FIG. 3, the user can set the maximum charge amount of the battery 190 currently connected such as 100%, 80%, 50%, and the like. This set value is notified to the embedded controller 170 from the utility software 210.

4 and 5 are diagrams illustrating an internal configuration of the battery 190.

As shown in these figures, the battery 190 is constituted by a control microcomputer 191, a memory 192, and a plurality of cells 193.

The control microcomputer 191 plays a role of managing the remaining capacity of the battery 190 or providing various information of the battery 190 to the outside through the SM-BUS 200.

The memory 192 is a nonvolatile memory such as an EEPROM and can record and read various management information.

Here, the battery 190 shown in FIG. 4 is a case where the arrangement of the cells 193 is "3 in series and 1 parallel", and the battery 190 shown in FIG. 5 has an arrangement of the cells 193 as ". 3 series 2 parallel ". Since the battery 190 shown in FIG. 5 has twice the number of cells compared with the battery 190 shown in FIG. 4, the maximum capacity also doubles. Therefore, when the battery charge current value is optimized for the battery 190 shown in FIG. 5, the battery 190 shown in FIG. 4 deteriorates the battery 190 unless the current value is about half that value. Will accelerate. On the other hand, when the battery 190 shown in FIG. 4 is optimized, in the case of the battery 190 shown in FIG.

FIG. 6 is a block diagram showing the battery 190 shown in FIG. 5 in more detail.

As shown in FIG. 6, the battery 190 includes, besides the control microcomputer 191, the memory 192, the six cells 193, a connection terminal 190A, a fuse 194, and the like. Switch (FET) 195 for charge control, switch (FET) 196 for discharge control, second protection IC 197 for overvoltage monitoring, thermistor 198 for monitoring the temperature of the cell, resistance for current detection And an analog front end (AFE) 190B as a signal interface between the analog system and the control microcomputer 191.

7 is a diagram for describing an outline of communication between the embedded controller 170 and the battery 190.

Between the embedded controller 170 and the battery 190 may receive various information defined in the Smart Battery System. Here, the SM-BUS 200 is used as the communication specification for information transfer.

The Smart Battery System is a battery management standard for calculating the remaining amount of secondary batteries or monitoring charge / discharge currents, and can be used by assembling battery packs such as notebook personal computers, digital still cameras, and electric vehicles.

The SM-BUS 200 is a two-wire (CLOCK and DATA) bus designed in consideration of communication between components of a computer (especially a semiconductor IC). Each device connected to the bus has a unique address, and the address can be used for peer-to-peer communication.

In this embodiment, the SM-BUS 200 is connected between the SM-BUS front end 170F in the embedded controller 170 and the SM-BUS front end 191F of the control microcomputer 191 in the battery 190. Through the method according to the regulation in the Smart Battery System, the remaining battery amount and the charging current value information are received. In addition, a custom command is added in accordance with the regulations of the Smart Battery System to manage the maximum charge value.

8 is a timing chart showing an example of communication via the SM-BUS 200 when the battery 190 is connected to the main body of the personal computer 100.

Communication through the SM-BUS 200 between the embedded controller 170 and the battery 190 is performed by the embedded controller 170 as a master device and the battery 190 as a slave device. That is, the battery 190 provides response information according to the command information issued from the embedded controller 170. For example, when the embedded controller 170 issues a " Relative State Of Charge " command (battery remaining amount acquisition) defined in the Smart Battery System, the battery uses the current remaining capacity of the embedded controller 170 as the master device. Reply to In other words, the embedded controller 170 may acquire various information included in the battery 190 by using the regulation by the smart battery system. In this embodiment, the regulation by such a smart battery system is used.

When the battery 190 is connected to the main body of the personal computer 100, an event occurs (step 801).

First, the embedded controller 170 issues a command for obtaining a charging current to the battery 190 (step 802).

The battery 190 returns the charging current as the first information stored in the memory 192 to the embedded controller 170 (step 803).

The embedded controller 170 sets the charging current to the battery 190 based on the obtained charging current information.

Next, the embedded controller 170 issues a command for acquiring the maximum charge capacity to the battery 190 (step 804).

Upon receiving this command, the battery 190 returns the maximum charging capacity as the first information stored in the memory 192 to the embedded controller 170 (step 805).

The embedded controller 170 sets the maximum charge capacity to the battery 190 based on the acquired maximum charge capacity information.

Next, the embedded controller 170 issues a custom command for acquiring the remaining battery capacity to the battery 190 (step 806).

When the battery 190 receives this command, the battery 190 returns the battery remaining amount of the battery 190 at that time to the embedded controller 170 (step 807).

The embedded controller 170 compares the remaining battery value acquired in step 807 with the maximum charging amount value acquired in step 805, and stops charging when the remaining battery amount is equal to or more than a target value.

Since the battery remaining amount of the battery 190 changes from time to time, the processing of steps 806 and 807 is executed periodically while the battery 190 is connected to the main body.

9 is a timing chart showing the operation of recording the maximum charge amount in the battery 190.

In this embodiment, the embedded controller 170 writes the maximum charge amount value to the battery 190 by a custom command. The battery 190 side treats the above maximum charge amount value as simple data. That is, since the battery 190 side performs the actual charge ON / OFF control on the embedded controller 170 side, it only plays a role of writing to the memory (nonvolatile memory) 192 to the last.

Specifically, when the embedded controller 170 wants to record data (maximum charge capacity value) on the battery 190 side, a custom command of the maximum charge capacity value WRITE is issued (step 901).

On the battery 190 side, the data (maximum charge capacity value) supplied by this custom command is recorded in the memory (nonvolatile memory) 192.

Fig. 10 is a flowchart showing the operation of the battery 190 side when the custom command (maximum charge capacity WRITE) or the like is received.

When the battery 190 receives the custom command (maximum charge capacity WRITE), the battery 190 writes data supplied with the command to a memory (nonvolatile memory) 192 such as an EEPROM.

On the battery 190 side, when a command is received from the command standby state (step 1001), respective operations are performed in accordance with the contents of the command (step 1002).

(1) In case of command of maximum charge capacity WRITE

Data is recorded in the memory (nonvolatile memory) 192 (step 1003).

(2) In case of command of maximum charge capacity READ

Data of the maximum charging capacity is obtained from the memory (nonvolatile memory) 192 (step 1004), and the data is returned to the embedded controller 170 as the master device (step 1005).

(3) For other commands

Processing in accordance with the received command is performed (step 1006).

11 is a flowchart showing the operation of the embedded controller 170 side in the control to stop charging at a particular battery charge value.

In the present embodiment, the following two cases are assumed when charging is stopped at a specific battery charge value.

When a CASE-1 battery is connected

(1) After detecting that the battery 190 is connected, the embedded controller 170 acquires target charge value information by a battery custom command.

(2) Through the SM-BUS 200, the remaining amount (charge amount) of the battery 190 is periodically read.

(3) When the target charge value acquired in STEP-1 is compared with the charge amount of the battery 190 acquired in STEP-2, when the remaining battery charge is equal to or greater than the target charge value, the battery charger 180 is instructed to stop charging. .

 When the target fill value setting is changed by the CASE-2 utility

(1) A setting change request and a target charging value are issued from the utility 210 to the embedded controller 170.

(2) The embedded controller 170 writes target charge value information supplied from the utility 210 into the battery custom command.

(3) The remaining amount (charge amount) of the battery 190 is periodically read through the SM-BUS 200.

(4) When the target charge value acquired in STEP-1 is compared with the charge amount of the battery 190 acquired in STEP-3, when the remaining battery charge is equal to or greater than the target charge value, the battery charger 180 is instructed to stop charging. .

Hereinafter, the control operation of the embedded controller 170 side will be described according to the flowchart shown in FIG.

The embedded controller 170 determines whether or not a change request for setting the target charge value has been issued from the utility 210 (step 1101).

When a change request for setting the target charge value is issued, the battery 190 is waited for connection (step 1102).

When the battery 190 is connected, a custom command for recording the battery maximum charge capacity value is issued to the battery 190 (step 1103).

On the other hand, even when the change request for setting the target charge value has not been issued in step 1101, when the change request for setting the target charge value is issued, the battery 190 waits for connection (step 1104).

When the battery 190 is connected, a custom command for acquiring the battery maximum charge capacity value recorded on the battery 190 side is issued to the battery 190 (step 1105).

After that, when the remaining battery level is acquired from the battery 190 (step 1106), it is determined whether to stop charging by comparing whether the remaining battery level is equal to or greater than the target charging value (step 1107), and when charging is stopped (step 1107). In step 1108, the battery charger 180 is instructed to charge off (step 1109). On the other hand, when it determines with charging, charging on is instruct | indicated to the battery charger 180 (step 1110).

12 is a flowchart illustrating an operation of the embedded controller 170 that controls charging current for the battery 190.

The embedded controller 170 waits for the battery 190 to be connected (step 1201).

When the battery 190 is connected, the charging current value information as the first information is obtained from the battery 190 side (step 1202).

The current value is determined based on the obtained charging current value information (step 1203), and the battery charger 180 is instructed to switch the charging current (step 1204).

As described above, in the technique relating to the charge control of the battery in the present embodiment, the battery has the maximum charge capacity value or the charge current value as the first information capable of controlling the charge on the battery side, and the battery as the first information. Since the charge capacity and the charge current to the battery 190 are controlled based on the maximum charge capacity value and the charge current value, the battery can be charged under desired conditions for each battery 190 without the user being aware of it.

That is, although already demonstrated, the table | surface shown in FIG. 13 is an example of the relationship of the capacitance and voltage in the case of the battery cell of nominal voltage 4.2V. However, there is a difference between the voltage and the capacity depending on the characteristics of the battery. Moreover, the lithium ion battery has the characteristic that the higher the battery cell voltage is, the easier it is to elute the positive electrode active material constituting the battery, and the performance deterioration of the battery becomes remarkable. In other words, if long-term storage is performed in a state where the cell voltage is high, the battery performance is degraded, the capacity deteriorates, and the battery life is shortened. Fig. 14 shows an image of capacity deterioration rate in the case of long-term storage in 100% (4.2V), 80% (4.0V), and 50% (3.7V) states. The battery charge amount is suppressed to 80% or 50% with respect to the maximum charge capacity (100%) of the battery, for example, thereby reducing the capacity deterioration of the battery. In this embodiment, the charge capacity can be set for each battery. More specifically, in the case of having a plurality of batteries, it is possible to make settings for the individual batteries according to the use purpose, such as focusing on the life of the batteries or giving priority to the operation time when driving the batteries. By storing the maximum charge amount as the first information on the battery side, the effort set by the user every time the battery is connected can be reduced, and the usability can be improved.

As described above, in a lithium ion battery, the charge / discharge cycle characteristics tend to deteriorate as the charge / discharge rate increases. The graph of FIG. 15 shows capacity deterioration when the charge / discharge cycle is repeated by changing the charge / discharge rate of a typical lithium ion battery cell. This figure shows that as the charge / discharge rate increases, the discharge capacity decreases and the battery life becomes short. In general, as shown in the graph of FIG. 16, when the charging rate is high, the charging time is short. On the contrary, when the charging rate is low, the charging time is long. For batteries with different capacities, optimal charging currents can be supplied to each. In this embodiment, since the charging current can be set for each battery according to the user's instruction, the deterioration caused by the charge / discharge cycle can be suppressed to make the battery life longer, or the charging time can be shortened by the appropriate charging current. Can be. By storing the charging current as the first information on the battery side, the effort set by the user every time the battery is connected can be reduced, and the usability can be improved.

In addition, this invention is not limited to said embodiment, A various modified example is conceivable.

For example, when a custom command such as the maximum charge amount cannot be added to the battery, the same function can be realized in the following means. On the main body side, unique information (e.g., serial number) included in a non-volatile memory such as an EEPROM is installed at a place accessible from the EC, and a setting of the maximum charge amount is associated. The unique information (for example, serial number) of the battery and the setting of the maximum charge amount are combined to store and manage the information in the nonvolatile memory of the main body. A battery generally used in a notebook personal computer stores a serial number in its internal memory and can read the information via an SM-BUS or the like. The battery can be discriminated by associating the serial number with the maximum charge amount.

Regarding the repetition of charge and discharge in the vicinity of the threshold value, there is a type in which different residual amount management calculation methods are used in the charging mode and the discharge mode depending on the battery. In that case, when switching from the charging mode to the discharge mode, the charge amount (the remaining amount information that can be obtained from the battery or the remaining amount information that the battery manages internally) may decrease. For example, it is assumed that the target charge amount is set to 80%. When the charge is stopped when the charge amount reaches 80%, the battery is switched from the charge mode to the discharge mode. In that case, there is a case where the remaining value becomes 79%. Therefore, when EC side starts recharging, it will become 80% immediately after that, and charging ON / OFF which stops charging is frequently repeated. Continuous repetition of charging and discharging may also cause deterioration in the battery. Therefore, it is preferable to provide hysteresis and control to not recharge until after the charge stops, for example, until the residual amount falls below 78%.

In addition, although the utility which operates on an OS was used as a man-machine interface in the said embodiment, it is also possible to improve usability by using input devices, such as a dedicated button, and display apparatuses, such as LED.

In addition, in the above-described embodiment, the appropriate charging current is automatically set for each battery when the battery is mounted, but the default is the uniform charging current regardless of the battery capacity, and a dedicated mechanism button or utility is used. It is also possible to provide the usability which can select the function of this invention by input devices, such as these.

In addition, apart from the charging current specified by the individual batteries, the charging current value for rapid charging is set by an option command or the like, and is rapidly established on the same principle as the present invention by a dedicated input device (mechanism button or utility, etc.). It is also possible to support the charging function.

In the above embodiment, the notebook-type personal computer has been described as an example of the electronic device. However, of course, the present invention can be applied to any electronic device having a battery. For example, the present invention can be applied to a portable game device, a mobile phone, or the like.

In addition, although the EC and the standard accompanying it were used for the exchange between the main body side and the battery side, it is of course also possible to exchange with other standards or dedicated devices.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing the configuration of a notebook personal computer as an electronic apparatus according to an embodiment of the present invention.

2 is a block diagram showing a relationship between an embedded controller, a battery, and a battery charger on the hardware side and utility software on the operating software (OS) side according to one embodiment of the present invention;

3 is a diagram illustrating an example of a utility screen according to an embodiment of the present invention.

4 is a diagram illustrating an internal configuration of a battery according to an embodiment of the present invention (No. 1).

5 is a diagram illustrating an internal configuration of a battery according to one embodiment of the present invention (No. 2).

FIG. 6 is a block diagram illustrating the battery shown in FIG. 5 in more detail. FIG.

7 is a view for explaining an outline of communication between an embedded controller and a battery according to one embodiment of the present invention;

8 is a timing chart showing an example of communication via SM-BUS when a battery is connected to a personal computer main body according to one embodiment of the present invention.

9 is a timing chart showing an operation of recording the maximum charge amount in a battery according to one embodiment of the present invention.

10 is a flowchart showing the operation of the battery side when receiving a custom command (maximum charge capacity WRITE) or the like according to one embodiment of the present invention.

Fig. 11 is a flowchart showing the operation of the embedded controller side in the control for stopping charging at a specific battery charge value according to an embodiment of the present invention.

12 is a flowchart showing the operation of the embedded controller side for controlling the charging current for the battery according to one embodiment of the present invention.

Fig. 13 is a table showing a relationship between cell voltage and capacity.

14 is a graph showing a relationship between a storage period and a deterioration rate when a filling amount is constant.

15 is a graph showing a relationship between charge and discharge rates and cycle characteristics.

16 is a graph showing the relationship between charge and discharge rate and charge time.

<Description of the code for describing the main parts of the drawing>

100: personal computer

110: CPU (Central Processing Unit)

120: liquid crystal display device (LCD)

130: Memory

140: North Bridge

150: Hard disk drive (HDD)

160: South Bridge

170: embedded controller (EC)

180: battery charger

190: Battery

200: SM-BUS (System Management Bus)

Claims (15)

A battery having first information for controlling charging, A main body operating with the battery as a power source, Charging means for charging the battery; Means for obtaining first information from the battery; Control means for controlling the charging means based on the obtained first information to perform charging according to different batteries An electronic device comprising a. The method of claim 1, The first information is the maximum charge amount of the battery, The control means stops charging the battery when the battery reaches the maximum charge amount. The method of claim 2, The maximum amount of charge of the battery as the first information can be set to a desired value for each corresponding battery. The method of claim 2, And the control means resumes charging the battery by the charging means when the battery reaches a predetermined or lower charging amount than the maximum charging amount after stopping the charging of the battery. The method of claim 1, Memory means for storing the unique number of the battery and the maximum charge amount of the battery in correspondence; The first information is a unique number of the battery, The control means obtains the maximum charge amount of the battery corresponding to the unique number of the battery as the obtained first information from the storage means, and stops charging the battery when the maximum charge amount of the battery is reached. An electronic device, characterized in that. The method of claim 1, The first information is a charging current of the battery, And the control means controls the charging means to perform charging according to different batteries based on the charging current of the battery as the first information. The method of claim 6, Has a setting function to set the charging current, The control means controls the charging means to charge the battery based on the charging current having a value of 1, which is normally set in advance, and when the charging current is set by the setting function as the first information. And charging the battery based on the charging current of the battery. The method of claim 6, And setting means for setting the charging current of the battery to a value capable of rapid charging than the normal time, And the control means controls the charging means when the setting means sets the value capable of the quick charging, and performs charging to the battery based on the set value capable of the quick charging. device. A charging method of an electronic device that operates with a rechargeable battery as a power source Have the first information for controlling charging in the battery, Obtain first information from the battery, And charging according to different batteries based on the obtained first information. The method of claim 9, The first information is the maximum charge amount of the battery, The control method according to claim 1, wherein the charging to the battery is stopped when the maximum amount of charge of the battery as the first information is reached. The method of claim 10, The maximum charging amount of the battery as the first information can be set to a desired value for each corresponding battery. The method of claim 9, The first information is a charging current of the battery, The control method according to claim 1, wherein charging is performed according to different batteries based on the charging current of the battery as the first information. With the battery body, Storage means for storing first information for controlling charging to the battery main body Battery comprising a. The method of claim 13, The first information is a maximum charge amount into the battery body. The method of claim 14, And the first information is a charging current to the battery main body.

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